/**
* Copyright (c) 2015 - 2019, Nordic Semiconductor ASA
*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form, except as embedded into a Nordic
* Semiconductor ASA integrated circuit in a product or a software update for
* such product, must reproduce the above copyright notice, this list of
* conditions and the following disclaimer in the documentation and/or other
* materials provided with the distribution.
*
* 3. Neither the name of Nordic Semiconductor ASA nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* 4. This software, with or without modification, must only be used with a
* Nordic Semiconductor ASA integrated circuit.
*
* 5. Any software provided in binary form under this license must not be reverse
* engineered, decompiled, modified and/or disassembled.
*
* THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS
* OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
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* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
#ifndef NRF_PDM_H_
#define NRF_PDM_H_
#include <nrfx.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
* @defgroup nrf_pdm_hal PDM HAL
* @{
* @ingroup nrf_pdm
* @brief Hardware access layer for managing the Pulse Density Modulation (PDM) peripheral.
*/
/** @brief Minimum value of PDM gain. */
#define NRF_PDM_GAIN_MINIMUM 0x00
/** @brief Default value of PDM gain. */
#define NRF_PDM_GAIN_DEFAULT 0x28
/** @brief Maximum value of PDM gain. */
#define NRF_PDM_GAIN_MAXIMUM 0x50
/** @brief PDM gain type. */
typedef uint8_t nrf_pdm_gain_t;
/** @brief PDM tasks. */
typedef enum
{
NRF_PDM_TASK_START = offsetof(NRF_PDM_Type, TASKS_START), ///< Starts continuous PDM transfer.
NRF_PDM_TASK_STOP = offsetof(NRF_PDM_Type, TASKS_STOP) ///< Stops PDM transfer.
} nrf_pdm_task_t;
/** @brief PDM events. */
typedef enum
{
NRF_PDM_EVENT_STARTED = offsetof(NRF_PDM_Type, EVENTS_STARTED), ///< PDM transfer is started.
NRF_PDM_EVENT_STOPPED = offsetof(NRF_PDM_Type, EVENTS_STOPPED), ///< PDM transfer is finished.
NRF_PDM_EVENT_END = offsetof(NRF_PDM_Type, EVENTS_END) ///< The PDM has written the last sample specified by SAMPLE.MAXCNT (or the last sample after a STOP task has been received) to Data RAM.
} nrf_pdm_event_t;
/** @brief PDM interrupt masks. */
typedef enum
{
NRF_PDM_INT_STARTED = PDM_INTENSET_STARTED_Msk, ///< Interrupt on EVENTS_STARTED event.
NRF_PDM_INT_STOPPED = PDM_INTENSET_STOPPED_Msk, ///< Interrupt on EVENTS_STOPPED event.
NRF_PDM_INT_END = PDM_INTENSET_END_Msk ///< Interrupt on EVENTS_END event.
} nrf_pdm_int_mask_t;
/** @brief PDM clock frequency. */
typedef enum
{
NRF_PDM_FREQ_1000K = PDM_PDMCLKCTRL_FREQ_1000K, ///< PDM_CLK = 1.000 MHz.
NRF_PDM_FREQ_1032K = PDM_PDMCLKCTRL_FREQ_Default, ///< PDM_CLK = 1.032 MHz.
NRF_PDM_FREQ_1067K = PDM_PDMCLKCTRL_FREQ_1067K ///< PDM_CLK = 1.067 MHz.
} nrf_pdm_freq_t;
/** @brief PDM operation mode. */
typedef enum
{
NRF_PDM_MODE_STEREO = PDM_MODE_OPERATION_Stereo, ///< Sample and store one pair (Left + Right) of 16-bit samples per RAM word.
NRF_PDM_MODE_MONO = PDM_MODE_OPERATION_Mono ///< Sample and store two successive Left samples (16 bit each) per RAM word.
} nrf_pdm_mode_t;
/** @brief PDM sampling mode. */
typedef enum
{
NRF_PDM_EDGE_LEFTFALLING = PDM_MODE_EDGE_LeftFalling, ///< Left (or mono) is sampled on falling edge of PDM_CLK.
NRF_PDM_EDGE_LEFTRISING = PDM_MODE_EDGE_LeftRising ///< Left (or mono) is sampled on rising edge of PDM_CLK.
} nrf_pdm_edge_t;
/**
* @brief Function for triggering a PDM task.
*
* @param[in] task PDM task.
*/
__STATIC_INLINE void nrf_pdm_task_trigger(nrf_pdm_task_t task);
/**
* @brief Function for getting the address of a PDM task register.
*
* @param[in] task PDM task.
*
* @return Address of the specified PDM task.
*/
__STATIC_INLINE uint32_t nrf_pdm_task_address_get(nrf_pdm_task_t task);
/**
* @brief Function for retrieving the state of the PDM event.
*
* @param[in] event Event to be checked.
*
* @retval true The event has been generated.
* @retval false The event has not been generated.
*/
__STATIC_INLINE bool nrf_pdm_event_check(nrf_pdm_event_t event);
/**
* @brief Function for clearing a PDM event.
*
* @param[in] event PDM event.
*/
__STATIC_INLINE void nrf_pdm_event_clear(nrf_pdm_event_t event);
/**
* @brief Function for getting the address of a PDM event register.
*
* @param[in] event PDM event.
*
* @return Address of the specified PDM event.
*/
__STATIC_INLINE volatile uint32_t * nrf_pdm_event_address_get(nrf_pdm_event_t event);
/**
* @brief Function for enabling PDM interrupts.
*
* @param[in] int_mask Mask of interrupts to be enabled.
*/
__STATIC_INLINE void nrf_pdm_int_enable(uint32_t int_mask);
/**
* @brief Function for retrieving the state of PDM interrupts.
*
* @param[in] int_mask Mask of interrupts to be checked.
*
* @retval true All specified interrupts are enabled.
* @retval false At least one of the given interrupts is not enabled.
*/
__STATIC_INLINE bool nrf_pdm_int_enable_check(uint32_t int_mask);
/**
* @brief Function for disabling interrupts.
*
* @param[in] int_mask Mask of interrupts to be disabled.
*/
__STATIC_INLINE void nrf_pdm_int_disable(uint32_t int_mask);
#if defined(DPPI_PRESENT) || defined(__NRFX_DOXYGEN__)
/**
* @brief Function for setting the subscribe configuration for a given
* PDM task.
*
* @param[in] task Task for which to set the configuration.
* @param[in] channel Channel through which to subscribe events.
*/
__STATIC_INLINE void nrf_pdm_subscribe_set(nrf_pdm_task_t task,
uint8_t channel);
/**
* @brief Function for clearing the subscribe configuration for a given
* PDM task.
*
* @param[in] task Task for which to clear the configuration.
*/
__STATIC_INLINE void nrf_pdm_subscribe_clear(nrf_pdm_task_t task);
/**
* @brief Function for setting the publish configuration for a given
* PDM event.
*
* @param[in] event Event for which to set the configuration.
* @param[in] channel Channel through which to publish the event.
*/
__STATIC_INLINE void nrf_pdm_publish_set(nrf_pdm_event_t event,
uint8_t channel);
/**
* @brief Function for clearing the publish configuration for a given
* PDM event.
*
* @param[in] event Event for which to clear the configuration.
*/
__STATIC_INLINE void nrf_pdm_publish_clear(nrf_pdm_event_t event);
#endif // defined(DPPI_PRESENT) || defined(__NRFX_DOXYGEN__)
/**
* @brief Function for enabling the PDM peripheral.
*
* The PDM peripheral must be enabled before use.
*/
__STATIC_INLINE void nrf_pdm_enable(void);
/** @brief Function for disabling the PDM peripheral. */
__STATIC_INLINE void nrf_pdm_disable(void);
/**
* @brief Function for checking if the PDM peripheral is enabled.
*
* @retval true The PDM peripheral is enabled.
* @retval false The PDM peripheral is not enabled.
*/
__STATIC_INLINE bool nrf_pdm_enable_check(void);
/**
* @brief Function for setting the PDM operation mode.
*
* @param[in] pdm_mode PDM operation mode.
* @param[in] pdm_edge PDM sampling mode.
*/
__STATIC_INLINE void nrf_pdm_mode_set(nrf_pdm_mode_t pdm_mode, nrf_pdm_edge_t pdm_edge);
/**
* @brief Function for getting the PDM operation mode.
*
* @param[out] p_pdm_mode PDM operation mode.
* @param[out] p_pdm_edge PDM sampling mode.
*/
__STATIC_INLINE void nrf_pdm_mode_get(nrf_pdm_mode_t * p_pdm_mode, nrf_pdm_edge_t * p_pdm_edge);
/**
* @brief Function for setting the PDM clock frequency.
*
* @param[in] pdm_freq PDM clock frequency.
*/
__STATIC_INLINE void nrf_pdm_clock_set(nrf_pdm_freq_t pdm_freq);
/**
* @brief Function for getting the PDM clock frequency.
*
* @return PDM clock frequency.
*/
__STATIC_INLINE nrf_pdm_freq_t nrf_pdm_clock_get(void);
/**
* @brief Function for setting up the PDM pins.
*
* @param[in] psel_clk CLK pin number.
* @param[in] psel_din DIN pin number.
*/
__STATIC_INLINE void nrf_pdm_psel_connect(uint32_t psel_clk, uint32_t psel_din);
/** @brief Function for disconnecting the PDM pins. */
__STATIC_INLINE void nrf_pdm_psel_disconnect(void);
/**
* @brief Function for setting the PDM gain.
*
* @param[in] gain_l Left channel gain.
* @param[in] gain_r Right channel gain.
*/
__STATIC_INLINE void nrf_pdm_gain_set(nrf_pdm_gain_t gain_l, nrf_pdm_gain_t gain_r);
/**
* @brief Function for getting the PDM gain.
*
* @param[out] p_gain_l Left channel gain.
* @param[out] p_gain_r Right channel gain.
*/
__STATIC_INLINE void nrf_pdm_gain_get(nrf_pdm_gain_t * p_gain_l, nrf_pdm_gain_t * p_gain_r);
/**
* @brief Function for setting the PDM sample buffer.
*
* The amount of allocated RAM depends on the operation mode.
* - For stereo mode: N 32-bit words.
* - For mono mode: Ceil(N/2) 32-bit words.
*
* @param[in] p_buffer Pointer to the RAM address where samples are to be written with EasyDMA.
* @param[in] num Number of samples to allocate memory for in EasyDMA mode.
*/
__STATIC_INLINE void nrf_pdm_buffer_set(uint32_t * p_buffer, uint32_t num);
/**
* @brief Function for getting the current PDM sample buffer address.
*
* @return Pointer to the current sample buffer.
*/
__STATIC_INLINE uint32_t * nrf_pdm_buffer_get(void);
#ifndef SUPPRESS_INLINE_IMPLEMENTATION
__STATIC_INLINE void nrf_pdm_task_trigger(nrf_pdm_task_t task)
{
*((volatile uint32_t *)((uint8_t *)NRF_PDM + (uint32_t)task)) = 0x1UL;
}
__STATIC_INLINE uint32_t nrf_pdm_task_address_get(nrf_pdm_task_t task)
{
return (uint32_t)((uint8_t *)NRF_PDM + (uint32_t)task);
}
__STATIC_INLINE bool nrf_pdm_event_check(nrf_pdm_event_t event)
{
return (bool)*(volatile uint32_t *)((uint8_t *)NRF_PDM + (uint32_t)event);
}
__STATIC_INLINE void nrf_pdm_event_clear(nrf_pdm_event_t event)
{
*((volatile uint32_t *)((uint8_t *)NRF_PDM + (uint32_t)event)) = 0x0UL;
#if __CORTEX_M == 0x04
volatile uint32_t dummy = *((volatile uint32_t *)((uint8_t *)NRF_PDM + (uint32_t)event));
(void)dummy;
#endif
}
__STATIC_INLINE volatile uint32_t * nrf_pdm_event_address_get(nrf_pdm_event_t event)
{
return (volatile uint32_t *)((uint8_t *)NRF_PDM + (uint32_t)event);
}
__STATIC_INLINE void nrf_pdm_int_enable(uint32_t int_mask)
{
NRF_PDM->INTENSET = int_mask;
}
__STATIC_INLINE bool nrf_pdm_int_enable_check(uint32_t int_mask)
{
return (bool)(NRF_PDM->INTENSET & int_mask);
}
__STATIC_INLINE void nrf_pdm_int_disable(uint32_t int_mask)
{
NRF_PDM->INTENCLR = int_mask;
}
#if defined(DPPI_PRESENT)
__STATIC_INLINE void nrf_pdm_subscribe_set(nrf_pdm_task_t task,
uint8_t channel)
{
*((volatile uint32_t *) ((uint8_t *) NRF_PDM + (uint32_t) task + 0x80uL)) =
((uint32_t)channel | PDM_SUBSCRIBE_START_EN_Msk);
}
__STATIC_INLINE void nrf_pdm_subscribe_clear(nrf_pdm_task_t task)
{
*((volatile uint32_t *) ((uint8_t *) NRF_PDM + (uint32_t) task + 0x80uL)) = 0;
}
__STATIC_INLINE void nrf_pdm_publish_set(nrf_pdm_event_t event,
uint8_t channel)
{
*((volatile uint32_t *) ((uint8_t *) NRF_PDM + (uint32_t) event + 0x80uL)) =
((uint32_t)channel | PDM_PUBLISH_STARTED_EN_Msk);
}
__STATIC_INLINE void nrf_pdm_publish_clear(nrf_pdm_event_t event)
{
*((volatile uint32_t *) ((uint8_t *) NRF_PDM + (uint32_t) event + 0x80uL)) = 0;
}
#endif // defined(DPPI_PRESENT)
__STATIC_INLINE void nrf_pdm_enable(void)
{
NRF_PDM->ENABLE = (PDM_ENABLE_ENABLE_Enabled << PDM_ENABLE_ENABLE_Pos);
}
__STATIC_INLINE void nrf_pdm_disable(void)
{
NRF_PDM->ENABLE = (PDM_ENABLE_ENABLE_Disabled << PDM_ENABLE_ENABLE_Pos);
}
__STATIC_INLINE bool nrf_pdm_enable_check(void)
{
return (NRF_PDM->ENABLE == (PDM_ENABLE_ENABLE_Enabled << PDM_ENABLE_ENABLE_Pos));
}
__STATIC_INLINE void nrf_pdm_mode_set(nrf_pdm_mode_t pdm_mode, nrf_pdm_edge_t pdm_edge)
{
NRF_PDM->MODE = ((pdm_mode << PDM_MODE_OPERATION_Pos) & PDM_MODE_OPERATION_Msk)
| ((pdm_edge << PDM_MODE_EDGE_Pos) & PDM_MODE_EDGE_Msk);
}
__STATIC_INLINE void nrf_pdm_mode_get(nrf_pdm_mode_t * p_pdm_mode, nrf_pdm_edge_t * p_pdm_edge)
{
uint32_t mode = NRF_PDM->MODE;
*p_pdm_mode = (nrf_pdm_mode_t)((mode & PDM_MODE_OPERATION_Msk ) >> PDM_MODE_OPERATION_Pos);
*p_pdm_edge = (nrf_pdm_edge_t)((mode & PDM_MODE_EDGE_Msk ) >> PDM_MODE_EDGE_Pos);
}
__STATIC_INLINE void nrf_pdm_clock_set(nrf_pdm_freq_t pdm_freq)
{
NRF_PDM->PDMCLKCTRL = ((pdm_freq << PDM_PDMCLKCTRL_FREQ_Pos) & PDM_PDMCLKCTRL_FREQ_Msk);
}
__STATIC_INLINE nrf_pdm_freq_t nrf_pdm_clock_get(void)
{
return (nrf_pdm_freq_t) ((NRF_PDM->PDMCLKCTRL << PDM_PDMCLKCTRL_FREQ_Pos) & PDM_PDMCLKCTRL_FREQ_Msk);
}
__STATIC_INLINE void nrf_pdm_psel_connect(uint32_t psel_clk, uint32_t psel_din)
{
NRF_PDM->PSEL.CLK = psel_clk;
NRF_PDM->PSEL.DIN = psel_din;
}
__STATIC_INLINE void nrf_pdm_psel_disconnect(void)
{
NRF_PDM->PSEL.CLK = ((PDM_PSEL_CLK_CONNECT_Disconnected << PDM_PSEL_CLK_CONNECT_Pos)
& PDM_PSEL_CLK_CONNECT_Msk);
NRF_PDM->PSEL.DIN = ((PDM_PSEL_DIN_CONNECT_Disconnected << PDM_PSEL_DIN_CONNECT_Pos)
& PDM_PSEL_DIN_CONNECT_Msk);
}
__STATIC_INLINE void nrf_pdm_gain_set(nrf_pdm_gain_t gain_l, nrf_pdm_gain_t gain_r)
{
NRF_PDM->GAINL = gain_l;
NRF_PDM->GAINR = gain_r;
}
__STATIC_INLINE void nrf_pdm_gain_get(nrf_pdm_gain_t * p_gain_l, nrf_pdm_gain_t * p_gain_r)
{
*p_gain_l = NRF_PDM->GAINL;
*p_gain_r = NRF_PDM->GAINR;
}
__STATIC_INLINE void nrf_pdm_buffer_set(uint32_t * p_buffer, uint32_t num)
{
NRF_PDM->SAMPLE.PTR = (uint32_t)p_buffer;
NRF_PDM->SAMPLE.MAXCNT = num;
}
__STATIC_INLINE uint32_t * nrf_pdm_buffer_get(void)
{
return (uint32_t *)NRF_PDM->SAMPLE.PTR;
}
#endif // SUPPRESS_INLINE_IMPLEMENTATION
/** @} */
#ifdef __cplusplus
}
#endif
#endif // NRF_PDM_H_